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FERRITE WATT LOSS TESTING:
COMMON MANUFACTURING
PROCESSES
Orlando, FL
February 8, 2012
Zack Cataldi
Product Development Engineer
Magnetics division of Spang & Co.
Agenda
• Magnetics Background
• Typical Watt Loss Measurements
• Test Procedure and Equipment
• Limits and Performance Curves
• Customer Correlation
Magnetics Background
• Manufacturer of Magnetic Cores
• Mn-Zn Ferrites (Power Ferrites)
• Distributed Air-Gap Powder Cores – MPP, Kool Mu, XFlux
• Strip Wound Cores – SiFe, 50% NiFe, 80% NiFe
• R&D Focused
• New material and core geometry development.
• Existing material improvement.
• Testing standardization.
• Customer specification correlation and design.
Typical Loss Measurements
• Power Ferrites – Core Loss
• Low losses at high frequencies and drive levels.
• Minimum loss is temperature dependent.
• R (2300
• P (2500
• F (3000
@ 100°C)
@ 80°C)
@ 25°C)
• Measurement taken on ungapped shapes or toroids.
Typical Loss Measurements
• High Perm Ferrites – Loss Factor
• Indication of the impedance frequency response.
• Cores are commonly used in common mode chokes.
• Typically measured at 25°C.
• Measurement is taken on ungapped shapes or toroids.
Typical Loss Measurements
• Nickel Zinc
• Commonly found in toroid, tube, multi-hole and cable shield form.
• Used in EMI Suppression.
• Low permeability (80 to 1700 ).
• Loss Factor and impedance at specific frequencies are common
specifications.
Test Procedure and Equipment
• Function Generator – Agilent 33120A
• Used to create test waveform (Sine wave at desired frequency).
• Amplifier – Amplifier Research
• Used to amplify test waveform.
• Oscilloscope
• To monitor current and voltage phase angles for power loss
measurement.
• Computer and Custom Program
• Core information stored in database.
• Controls testing once cores are loaded in cabinet.
• Processes information from oscilloscope to calculate watt loss.
• Can also be operated in manual mode for non-standard cores.
Test Procedure and Equipment
Function
Temperature
Generator
Cabinet
Amplifier
Tuner
Oscilloscope
Test Procedure and Equipment (cont.)
• Temperature Cabinet
• 32 Cores at a time
• -60°C to 200°C
2
1
Test Procedure and Equipment (cont.)
• Watt Loss
• Cores are wound with two strands bifilar wire.
• Drive winding and pick up winding.
• Use Faraday’s Law to calculate # of turns
• Drive voltage greater than 1 Volt but less than 60 V.
• Wire size acceptable for signal current.
• 6 Cores per lot are tested
• Loss Factor
• Cores wound with 10 turns.
•
• Rs and Ls as well as
i
are measured on an LCR bridge.
Limits and Performance Curves
• Typical performance curves are provided in the catalog.
• Based on empirical data from toroid tests.
• Mistake is to use these as limits in design.
• Spec sheets have the limits.
• Curve fit equations also available for use in modeling software.
• Good estimation tool, but curves are most accurate.
P Material Curve (@ 100° C)
Limits and Performance Curves
• Limits are defined for each part number.
• Provided on each individual spec sheet.
ZP-42915-TC
CORE LOSSES
PL max
Production lot limit
Max avg
Test conditions
674 mW
3
(123 mW/cm )
614 mW
3
(112 mW/cm )
100 kHz, 100 mT, 100°C
ZW-42915-TC
ELECTRICAL LOSSES
tan δ / µi
Production lot limit
Average
-6
≤ 3 ·10
-6
≤ 45·10
≤ 3.5·10
Test conditions
-6
10 kHz
-6
100 kHz
0.5 mT, 25ºC
≤ 55·10
Customer Test Correlation
• Customers typically do not test for watt loss
• Equipment is not available to them, wouldn’t be useful anyway.
• Q Factor is a common measurement for power materials.
• Relates to efficiency of the wound unit.
•
• Problem: Measures core and winding properties, not dependent on
watt loss alone.
• Q is not guaranteed by a core supplier, only losses that they are
measuring are guaranteed.
• Temperature Rise
• Source of heat is from losses.
• Both material and winding losses contribute.
• In ferrites, wire losses would most likely be the culprit.
• Correlation is the only logical action.
Questions?